期刊
ECOSPHERE
卷 12, 期 10, 页码 -出版社
WILEY
DOI: 10.1002/ecs2.3765
关键词
Accipiter; Falco; geographic assignment; hydrogen isotopes; isoscape; migration; strontium isotopes
类别
资金
- UC Geology Department
- North American Falconers Association
- UC Undergraduate STEM Experiences award
- NSERC [RGPIN-2019-05709]
This study focuses on using strontium and hydrogen isotopes in feathers to determine the natal origin of migratory raptors. By calibrating single-isotope models and comparing hydrogen and strontium isotopes, the dual-isotope approach significantly improves predictive precision. The combination of isotopic data from feathers with other methods enhances our ability to predict the natal range of migratory birds.
Understanding seasonal mobility, population connectivity, and site fidelity is critical for managing and preserving migratory species. We investigated the potential of coupling strontium (Sr-87/Sr-86) and hydrogen (delta H-2) isotopes in feathers for quantitatively constraining natal origin for juvenile migratory predatory birds (raptors) using a probabilistic framework. We first calibrated single-isotope models that predict spatial isotope variability in raptor feathers (called isoscapes) by analyzing and compiling isotope data for juvenile birds with known origins in North America and comparing their values to existing isotopic baselines in precipitation (for delta H-2) and bioavailable strontium (for Sr-87/Sr-86). We then compared the potential of hydrogen and strontium isotopes for refining geographic assignments either independently or combined. While yielding very different probability maps, hydrogen and strontium isotopes performed equally well at constraining regions of natal origin. However, thanks to the complementarity of these isotopes, dual delta H-2 and Sr-87/Sr-86 assignments increased predictive precision by an order of magnitude compared to either isotope alone. Lastly, we used the models to predict natal origin for juveniles with unknown origins that were sampled in southwestern Idaho, USA, during their autumn migration. The precision of geographic assignments for birds with unknown origins varied. Nevertheless, dual-isotope assignments clearly distinguished individuals born outside of southwestern Idaho, and overall, predicted geographic assignments matched breeding ranges for the study species. Quantitative dual-isotope geographic assignments enhance our ability to predict natal range of migratory raptors and complement other methods for monitoring movement and population connectivity. Combining isotopic data from feathers with other intrinsic geochemical and genetic data, as well as extrinsic markers, such as transmitters or bands, and niche-modeling approaches will further refine key nesting areas for migratory birds.
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